DE2014526B2 - Multistage staircase waveform generator - has switching stage which controls increment changes in voltage for selected waveform steps - Google Patents

Abstract

A 'staircase' voltage waveform generator uses a number of stages that are controlled in sequence and operate without time variations. The voltage supply is coupled to the first stage across a divider (14a) with a capacitor (10a) coupled to ground. The common point connects over a compensating stage (16a) with a variable resistor (20a) to the anode of a thyristor (22a). Between cathode and control electrode is the secondary winding of a pulse transformer (28a). A trigger pulse from an external source (30a) is applied to the primary winding. A diode (32a) is coupled to a series of Zener diodes (36) and a second diode (38a) connects with the output (44) over an impedance (4z). Individual switching stages (22) connect with the Zener diode series (36).

Description

The present invention relates to a staircase voltage generator for generating a voltage with η independent, individually triggered voltage levels.

When generating multiple images in image converter ^ cameras is used to deflect the electron image; a stepped tension is required. It is often required that the individual tension levels of the stairway span can be triggered at any, often very long, time intervals. In general ₍ , ₅ however, it is not necessary for the voltage to be constant during the entire period between two successive voltage jumps,

There is already a circuit arrangement from DT-AS 12 47 386 known for generating two counter-rotating, step-shaped voltages, the one Contains voltage divider with taps that can be short-circuited by current gates as desired. Because the high capacities of the current gates connected in parallel with the voltage divider are the same Circuit difficult to generate steep voltage jumps.

It is also known from DT-AS 10 93 902 a circuit arrangement for generating a step-adjustable voltage, which contains a number of gas discharge tubes, each connected with a series resistor and all together with a common load resistor in series between two terminals of a voltage source are. The tubes are ignited one after the other, and the resulting discharge currents flow through the common resistor and generate a corresponding voltage drop across it. The disadvantage of this circuit is that the voltage of the stairs depends on the supply voltage and on the internal resistance of the gas discharge tubes acting as switches.

A circuit arrangement known from DT-AS 11 40 970 for generating has the same disadvantages a step-shaped oscillation, which contains a voltage divider, whose division ratio by means of an electronic switching device is gradually changed for each staircase. In the known case takes place the control of the switching device by a periodic control pulse sequence, so that the duration of the individual stairs cannot be varied at will.

From the magazine "radio fernsehen elektronik" 18 (1969), issue 6, pages 170 to 172, a staircase voltage generator is known, in which the voltage levels by a constant current on a voltage divider can be generated with different taps. With this circuit arrangement, voltage levels with rise times in the nanosecond range, such as she z. B. are required in short-term photography with image converter cameras, do not generate.

It has also already been proposed, each voltage step by means of a step-shaped voltage a resistor through which a capacitor is discharged. The resistances for the different voltage levels are connected in series so that the voltage drops add up. With such a circuit arrangement, it is true that very steep voltage jumps can be generated which However, the voltage of each voltage level depends on the voltage of all previous voltage levels, see above that the total duration of the staircase tension are relatively narrow limits.

The present invention is accordingly based on the object of specifying a staircase voltage generator which generates a staircase-shaped voltage with π independent, individually triggerable voltage levels that can follow one another at any time intervals and, following the voltage jump, for a predetermined period of time

have very good constancy, delivers.

According to the invention, this object is achieved in a staircase voltage generator of the type mentioned at the beginning To solved in that a capacitor is provided for each voltage level, which is connected to a voltage source for charging the capacitor to a Voltage that is at least slightly higher than the voltage of the voltage level concerned is connected and is bridged with a discharge circuit, the one open in the idle state, individually includes closable switch in series with a working resistor, one terminal of which with one end of a Series connection of voltage stabilizing components is connected, the taps corresponding to the has desired voltage levels that the other terminal of the load resistor via a diode with the associated tap of the series circuit from the voltage stabilizing components and via a Another diode is coupled to a terminal of a common output impedance, the other terminal is connected to the mentioned end of the series circuit, the two diodes for the at with the switch closed at the associated load resistor, the voltage dropping in the direction of flow is polarized, that the switches are coupled to a control device, which they in the order to be generated Voltage levels, which in turn correspond to the charging voltages of the capacitors assigned to the switches, allowed to close as desired and that the output impedance connected to output terminals is.

In the staircase voltage generator according to the invention, the individual voltage levels can be used trigger practically any time, so you are not tied to a fixed time sequence. In addition, you can very short rise times of the voltage levels, high level voltages (over 1 kV) and low output impedances reach.

Further developments and refinements of the invention are characterized in the subclaims.

In the following an embodiment of the invention is explained in more detail with reference to the drawing; it shows

Fig. Ί a circuit diagram of an embodiment a staircase voltage generator according to the invention, which is used to generate a positive voltage serves two voltage levels;

F i g. 2 shows a graphical representation of the temporal course of the output voltage U of the circuit arrangement according to FIG. 1.

The staircase voltage generator according to the invention contains, for each of the π voltage levels to be generated, one of π circuit units, which in principle have the same structure. Corresponding components of these circuit units have therefore been given the same reference numbers. The components of the various circuit units are distinguished by adding small letters. To explain the circuit design of the staircase voltage generator according to FIG. 1 is therefore sufficient to explain in more detail only the circuit unit used to generate the first voltage stage A (FIG. 2).

The circuit unit for generating the first voltage stage A contains a capacitor 10a, one terminal of which is connected to ground and the other terminal 12a of which is connected to a voltage source which is used to charge it and which contains a voltage divider 14a . The terminal 12a is also connected in parallel via a compensation element lba a capacitor 18a and a preferably adjustable resistor 20a, coupled to the anode of a thyristor 22a, the cathode of which is connected to a terminal 24a of a load resistor 26a, the other terminal of which is connected to ground. The secondary winding of a pulse transformer 28a is connected between the control electrode and cathode of the thyristor 22a, the primary side of which is coupled to an input terminal 30a to which an ignition pulse can be supplied by a control device (not shown).

The terminal 24a is connected to ground on one side via a diode 32a with a tap 34a Series connection of Zener diodes 36 and a second diode 38a with a terminal 40 of a Output impedance 42 is coupled, shown as a potentiometer resistor, and to an output terminal 44 is connected.

The voltage divider 14a is dimensioned in such a way that the capacitor 10a is charged to a voltage such that the voltage dropping across the thyristor 22a at the load resistor 26a when the capacitor is discharged and coupled to the tap 34a via the diode 32a has such a value, that the desired voltage Ua of the first voltage stage occurs at the terminal 34a for a desired period of time Tn following the voltage jump A generated by the triggering of the thyristor 22a.

The compensation element 16a, with its capacitor 18a, determines the steepness of the voltage jump A when the thyristor 22a is triggered, while the resistor 20a (in conjunction with the resistor and its parallel resistor 42-26a) determines the discharge current and thus the usable time Tn .

The circuit unit for generating the second voltage jump B and the voltage stage with the voltage Ub is constructed in exactly the same way as the circuit unit described above for generating the first voltage jump A. The terminal 246 of the operating resistor 26b is, however, switched off via the diode 32b with a tap 346 of the series circuit coupled to the Zener diode 36, which is further away from ground than the tap 34a and is selected such that when the capacitor 106 discharges via the triggered thyristor 226 at the tap 346, the stable voltage Ub of the second voltage stage occurs. This voltage is coupled to the terminal 40 of the working impedance 42 via the diode 386.

The charging voltage generated by means of the voltage divider 146 at the terminal 126 is of course correspondingly higher than the voltage at the terminal 12a. When the capacitor 106, which generates the second voltage stage with the voltage Ub , is discharged, the diodes 32a and 38a are reverse-biased and thereby decouple the circuit unit for generating the first voltage stage, in particular the working resistor 26a, from the series connection of the Zener diodes 36 and from the working impedance 42 The voltage of the second voltage stage is therefore independent of the discharge state of the capacitor 10a. The same naturally also applies to any further stages. The time between the triggering of two successive voltage levels, e.g. B. A and B is therefore completely arbitrary.

The circuit arrangement described can

can of course also be expanded for more than two voltage levels. In this case the Series connection also contain further Zener diodes 36 connected to tap 346, as shown in dashed lines is indicated and the circuit point 24c, not shown, would then be the next circuit unit Coupled with the next tap and terminal 40 via a diode each, etc.

The circuit arrangement according to FIG. 1 can be used without difficulty for the generation of negative Modify staircase voltages. In this case, the capacitor 10 and the thyristor would simply have to 22 are swapped (the cathode of the thyristor is then connected to ground and the anode to the Terminal 12a, and the polarity of the diodes including

the zener diodes would have to be reversed.

In a practical embodiment, the rise time of the stairs (duration of the voltage jumps) was around 200 to 300 nsec, the linearity of the stairs was better than 1 V _JS within a time span T _n of 25 μβεΰ and the voltage per stair was 400 to 500 V.

If the _{time interval between two voltage levels corresponding to T 2} -Tl is so large that the voltage of the previous level has essentially subsided by the time the following voltage level is triggered, the switches can be closed in the order of decreasing charging voltages of the associated capacitors.

15th

1 sheet of drawings

Claims (4)

Patent claims: 1. Staircase voltage generator for generating a voltage with η independent, individually triggerable voltage levels, characterized in that a capacitor (10) is provided for each voltage level, which is connected to a voltage source (14) for its charging to a voltage that is at least slightly greater than that The voltage of the voltage level in question is connected and bridged with a discharge circuit which contains an individually closable switch (22), which is open in the idle state, in series with a working resistor (26), one terminal (ground) of which is connected to one end of a series circuit of voltage-stabilizing components (36) is connected, the taps (34) according to the desired voltage levels (Ua, Ub ...) that the other terminal (24) of the working resistor via a diode (32a,) with the associated tap (34) the series connection of the voltage-stabilizing components (36) and a further diode (38) with a terminal (40) a common output impedance (42), the other terminal of which is connected to the mentioned end of the series circuit, the two diodes (32, 38) being polarized in the forward direction for the voltage dropping across the associated load resistor (26) when the switch (22) is closed that the switches are coupled to a control device which allows them to be closed in the order of the voltage levels to be generated, which in turn correspond to the charging voltages of the capacitors assigned to the switches, and that the output impedance (42) is connected to output terminals (44, ground) connected is. 2. Treppenspannungsger.erator according to claim 1, characterized in that the discharge circuit a compensation element (16) from the parallel connection of a capacitor (18) and preferably one adjustable resistor (20) contains. 3. staircase voltage generator according to claim 1 or 2, characterized in that the voltage-stabilizing Components are zener diodes. 4. Staircase voltage generator according to claim 1, 2 or 3, characterized in that the Control device the switches (22) in the order of increasing charging voltage of the relevant Switches associated capacitors (10) closes. since the voltage normally only lasts for a relatively short time afterwards a voltage jump is required. On the other hand, the voltage jump should be as steep as possible and the The voltage should be as constant as possible during a certain period of time following the voltage jump